US20100174173A1

US20100174173A1 - Implantable Medical Device Using Palladium

Info

Publication number: US20100174173A1
Application number: US12/709,290
Authority: US
Inventors: James M. Carlson; Donald Patterson
Original assignee: Cook Inc
Current assignee: Cook Inc
Priority date: 2005-12-13
Filing date: 2010-02-19
Publication date: 2010-07-08
Also published as: EP1960012A2; DE602006016477D1; EP1960012B1; WO2007070544A3; ATE478695T1; WO2007070544A2; US20070162108A1

Abstract

The present invention provides an improved implantable medical device comprising at least one portion made of a radiopaque material selected from the group consisting of various palladium alloys, including a palladium alloy having, by weight, rhenium in the range of up to about 20 percent, and preferably rhenium at about 14 percent of the alloy, by weight. The present invention further provides a wire guide, an embolization coil, a marker band, a stent, a filter, an RF ablation coil, and an electrode having at least one portion made of the radiopaque material.

Description

RELATED APPLICATIONS

This application is a continuation application of application Ser. No. 11/638,309, filed Dec. 13, 2006, which claims the benefit of the filing date under 35 U.S.C. §119(e) of Provisional U.S. Patent Application Ser. No. 60/749,927, filed Dec. 13, 2005. All of the foregoing applications are hereby incorporated by reference.

TECHNICAL FIELD

The present invention generally provides an implantable medical device for positioning in a body passage or lumen that is made at least in part of palladium for its tensile strength, radiopacity and MRI compatibility.

BACKGROUND

It has become common to treat a variety of medical conditions by temporarily or permanently introducing an implantable medical device partly or completely into the esophagus, trachea, colon, biliary tract, urinary tract, vascular system or other location within a human or veterinary patient. Many treatments of the vascular or other systems entail the introduction of a device such as a stent, a catheter, a balloon, a wire guide, a cannula, a filter or the like.
For example, as described in U.S. Pat. No. 6,348,041, medical wire guides for vascular procedures, such as angioplasty procedures, diagnostic and interventional procedures, percutaneous access procedures, or radiological and neuroradiological procedures in general, traditionally comprise an elongated core element with one or more tapered sections near the distal end thereof and a flexible helical coil disposed about the distal portion of the core element. The distal extremity of the core element or a separate safety ribbon which is secured to the distal extremity of the core element extends through the flexible coil and is secured to the distal end member of the wire guide, which is a rounded member at the distal end of the helical coil. Torquing means are provided on the proximal end of the core element to rotate and steer the wire guide while it is being advanced through a patient's vascular system.
In order to follow the position of the wire guide within the body during a vascular procedure, it is desirable to use a material for the wire guide that is radiopaque for exposure to X-rays and MRI compatible for exposure to a magnetic field so as to make the tip portion of the wire guide visible on a screen. For example, the flexible helical coil of the wire guide may include a wire of radiopaque and/or MRI compatible material, or the distal end member of the wire guide may be designed as a coil of radiopaque and/or MRI compatible material that serves as a very soft and pliable tip member. The physician views the progress of the wire guide on a screen and makes the distal end of the wire guide enter and follow tortuous vascular vessels from the entry site through the various vascular branches to the target site by pushing and rotating the proximal end of the wire guide outside of the patient.
In connection with the advancement of the wire guide or once the wire guide has been positioned at the desired site, a wide variety of medical devices may be directed to the target site along the wire guide by simply sliding the device over the wire guide and advancing the device to the distal end of the wire guide. A typical medical device is a catheter, and very often a catheter and the wire guide are introduced in a common procedure where the wire guide is advanced a distance in front of the catheter, then the catheter is advanced over the wire guide, followed by a further advancement of the wire guide. Following placement of the catheter or other device, the wire guide can be removed if desired.
Once a catheter is placed in the vascular system, an embolization device can be positioned in a blood vessel to limit or stop the free flow of blood in an area of the blood vessel. As described in U.S. Pat. No. 6,776,788, embolization devices in the form of coils where a wire body is formed by a thread extending helically around the center line of the wire body are well-known. One example of an endovascular field of application for embolization devices for percutaneous, transluminal insertion using minimally invasive techniques, can be occlusion of an aneurism to prevent rupture of the vessel wall with resulting bleeding. Aneurisms may occur anywhere in the vascular system, but particularly cerebral and abdominal aneurisms require treatment to avoid life-threatening conditions. Another application is occlusion of arteriovenous malformations (AVM), where short-circuiting of arteries and veins looking like skeins of wool may occur, or occlusion of arteriovenous shunts or fistulas, which are major short-circuits between the artery side and the vein side in the vascular system with resulting heavy undesired blood flow. A fourth example of an application is blocking of the blood flow to a tumor, and a fifth, closure of traumatically conditioned blood flows owing to incised wounds or other bodily injuries or gastrointestinal bleeding.
In many current procedures, a wire guide mounted with the embolization device is pushed in through the catheter. When the wire body leaves the distal end of the catheter, it seeks to assume the predetermined shape. If the size and shape of the device are deemed suitable for the vessel geometry at the site of placement, the wire body is disconnected from the wire guide. Conventionally, the predetermined shape of the embolization device is made so that the wire body is helical with a helix diameter of the same size or slightly larger than the relevant vessel lumen, so that the wound wire body exerts an abutment pressure against the vessel wall. If the helix diameter is too large, the pressure against the vessel wall may become injuriously high, and if it is too small, the wire body can easily be released and drift away.
It is desirable to use a material for the embolization coil that is radiopaque to X-rays to indicate the position of the embolization coil once it is inserted in a blood vessel. In addition, since embolization coils remain in the vascular system for prolonged periods of time, it is desirable to use a material that is substantially free of nickel. Nickel ions are considered an undesired contaminant in the bloodstream of a patient because it is believed that they can lead to problems with cytotoxicity, carcinogenicity, genotoxicity and short to long term or chronic systemic toxicity. For example, it is known that nickel ions can elute from austenitic stainless steel implants creating problems in orthopedic patients contributing to tumor formation or artificial joint loosening and corrosion and wear.
It is known to use austenitic stainless steel alloy wire, such as double spring tempered 304V austenitic stainless steel, for the manufacture of implantable medical devices in order to obtain the desired strength, stiffness and flexibility for forming the wire into desired flexible shapes and navigating the arteriovenous malformations and other vascular lesions in small vessel anatomy. In addition, austenitic stainless steel alloys typically have a density close to 8 g/cm³, which renders them moderately radiopaque to allow a physician to view the progress of the device to a target site on a screen. However, austenitic stainless steel alloys are not very MRI compatible because they are ferromagnetic with a magnetic susceptibility in the neighborhood of 3000×10⁻⁶SI. This means that a significant size artifact is created when the coil is subjected to a magnetic field during a MRI procedure. The artifact can potentially obscure the anatomical features of interest making a MRI guided diagnostic and or interventional embolization procedure very difficult to conduct. In addition, austenitic stainless steels contain a significant percentage of nickel, typically between 8-12% depending upon the grade. It is also known to use platinum based alloys, such as Pt-8% W, Pt—Ni or Pt—Ir alloys, for the manufacture of implantable medical devices. These alloys have enhanced MRI compatibility and radiopacity compared to austenitic stainless steel alloys.

BRIEF SUMMARY

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an illustrative wire guide;

FIG. 2 shows a partial, longitudinal section through the wire guide of FIG. 1;

FIGS. 3-6 show partial, longitudinal views of embodiments of the wire guide of FIG. 1 with a radiopaque marker made at least in part of a palladium based alloy according to the invention;

FIG. 7 shows an illustrative embolization coil made at least in part of a palladium based alloy according to the invention;

FIG. 8 shows a partially sectioned view of the embolization coil of FIG. 7 in an elongated condition prior to being wound into a conically helically shaped coil; and

FIG. 9 shows the longitudinally extending coil of FIG. 8 wound around the tapered surface of a mandril to form a conically helically shaped coil.

DETAILED DESCRIPTION

The following provides a detailed description of currently preferred embodiments of the present invention. The description is not intended to limit the invention in any manner, but rather serves to enable those skilled in the art to make and use the invention.
FIG. 1 shows an illustrative medical wire guide denoted by 1 and having a distal end 2 capable of being advanced to a target site in the vascular system and a proximal end 3 that is kept outside the patient's body. A shaft portion 4 extends from the proximal end towards the distal end and carries near the proximal end a handle 5 releasably secured to the wire guide. The wire guide can typically have a length in the range of 30-600 cm and a maximum outer diameter in the range of 0.204-1.321 mm (0.008-0.052 inches). It can also include several segments where the proximal segment has a larger diameter than one or more intermediate segments which has/have larger diameters than the distal segment. When such a wire guide follows a tortuous vessel path involving several sharp bends, loops and the like, it is desirable that a turning of handle 5 results in a similar turning of the distal end 2.
The shaft portion 4 can include a solid shaft which is of a metallic material such as medical grade stainless steel or Nitinol. In that case a coiled distal portion 6 is fixed onto and in extension of the shaft portion. However, in the preferred embodiment the coiled portion continues from the distal to the proximal ends, and the use of a solid shaft is made superfluous. The coiled portion ends distally at the distal end 2, which is a member having a soft front end termination, such as a rounded front or a front of very flexible material or very flexible configuration. Distal end member 2 can be a solder, or a sphere that can be laser welded, for example, onto the distal end of the coiled distal portion 6.
In the embodiment depicted in FIG. 2, a wound group of three wires 10 extends from a position at the shaft portion 4 to the distal end member 2. Three wires 7, 8 and 9 have been placed next to each other and have been wound in a common operation into the wound group of three wires 10 with a pitch angle α of the individual wire of about 40 degrees. The wire 7, 8 or 9 is of a linear elastic material, such as stainless steel, titanium or tantalum, or it is made of a superelastic alloy, such as Nitinol. The pitch angle is the included angle between the longitudinal axis of the wire guide and the center axis of the relevant wire 7, 8 or 9. The size of the pitch angle depends on the diameter of the wire, the diameter of the wire guide, and of the number of wires in a group. The most preferred pitch angle is in the range of 50 to 70 degrees. Also, if pushability is the most important criteria, the pitch angle can be chosen in the range of 35-50 degrees, for example. If bending flexibility is most important, the pitch angle can be chosen in the range of 70-76 degrees, for example. However, the combination of torque transferral, pushability and transverse flexibility is normally well-balanced for pitch angles in the range of 50-68 degrees. The wire guide is made by placing a group of from one to eight wires in a row next to each other, such as according to the desired pitch angle, after which the group of wires is wound about a mandrel. Then the mandrel with the coiled wires can be subjected to heat treatment in order to remove residual stresses from the wires. After the heat treatment the mandrel is removed from the coiled wires.
In order to make the tip portion of the wire guide 1 more visible on a screen it is desirable to use some kind of radiopaque material, such as a palladium based alloy which has equivalent or improved radiopacity, ultimate tensile strength and/or magnetic susceptibility compared to known platinum based alloys suitable for use in medical wire guides. For example, it is believed that a palladium alloy having, by weight, about 10 percent rhenium is preferable. This particular composition is biocompatible and hemocompatible and has the following material properties: a radiopacity approximately equivalent to known platinum alloys with 8 percent tungsten; a nominal ultimate tensile strength of about 210 ksi, which ultimate tensile strength can be in the range of about 200-230 ksi, as compared to a nominal ultimate tensile strength of about 200 ksi, which ultimate tensile strength can be in the range of about 180-230 ksi, for known platinum alloys with 8 percent tungsten; and a magnetic or bulk susceptibility of about 50×10⁻⁶SI when measured using a Guoy balance, as compared to a magnetic or bulk susceptibility of about 250×10⁻⁶SI when measured using a Guoy balance for known platinum alloys with 8 percent tungsten or a magnetic or bulk susceptibility of about 230×10⁻⁶SI when measured using a Guoy balance for known platinum alloys with 10 percent iridium. By further comparison, known 304V austenitic stainless steel has an ultimate tensile strength of about 300 ksi and a magnetic or bulk susceptibility of about 3200×10⁻⁶SI when measured using a Guoy balance, and known Inconel® nickel chromium alloy 625 has an ultimate tensile strength of about 300 ksi and a magnetic or bulk susceptibility of about 1200×10⁻⁶SI when measured using a Guoy balance.
It has been recognized by the present inventors that the high tensile strength properties of the palladium alloy may be improved by increasing the amount of rhenium in the composition or by modifying the drawing and annealing process for the wire. For example, it has been found that a palladium alloy having, by weight, about 12 percent rhenium approximately doubles the ultimate tensile strength (and the Brinell hardness) of palladium, whereas a palladium alloy having, by weight, about 15 percent rhenium approximately triples the ultimate tensile strength (and the Brinell hardness) of palladium. Further, it has been found that a palladium alloy having, by weight, about 14 percent rhenium also is preferable. This particular composition also is biocompatible and hemocompatible and has a radiopacity in the range of a platinum alloy with 8 percent tungsten, an ultimate tensile strength of about 270 ksi, and a magnetic or bulk susceptibility of about 25×10⁻⁶SI when measured using a Guoy balance.
Alternatively, it is believed that a palladium wire having, by weight, about 22.5 percent silver and about 10 percent copper may be used. This particular composition has a radiopacity approximately equivalent to a platinum alloy with 8 percent tungsten; an ultimate tensile strength of about 190 ksi; and a magnetic or bulk susceptibility of about 50×10⁻⁶SI when measured using a Guoy balance.
In addition, the following Table 1 shows several palladium based alloys (all percentages shown by weight) suitable for use in wire guides, which are believed to offer equivalent or better material properties, including tensile strength, radiopacity and MR compatibility, compared to known platinum based alloys and austenitic stainless steel alloys. In particular, these palladium alloys are believed to exhibit higher tensile strength and at least equivalent radiopacity compared to known platinum alloys and austenitic stainless steel alloys.
As will be readily understood by the skilled person, the alloys of the present invention may consist exclusively of the specifically recited elements, such that the alloys are in a substantially pure form. In other words, palladium makes up the remainder of the recited alloy, to the exclusion of all other (non-recited) substituents. Alternatively, it is to be understood that the presently recited palladium alloys may also comprise other substituents as well as those specifically recited, as may advantageously be desired. Of course, in either situation the skilled person will also be aware that the recited alloys may also contain various impurities and other small amounts of matter, but in such amounts so as not to effect the advantageous properties of the inventive alloys. Preferably, such trace amounts of material will be present in less than e.g. 1000 ppm. One such element that may not be desired to be present in the present alloys is e.g. nickel. This has been found to be a potential allergen to those allergic to the metal, and thus is undesirable in medical implants which are to remain in the body for substantial amounts of time, e.g. embolization coils.

TABLE 1

Alloy	Density (g/cm³)

CP Pd	12
Pd—xRe	12-13.8
(x = 0 to 20%)
Pd—xRu	12-12.04
(x = 0 to 10%)
Pd—xMo	12-11.5
(x = 0 to 30%)
Pd—xW	12-14.2
(x = 0 to 30%)
Pd—xRh	12-12.14
(x = 0 to 30%)
Pd—xIr	12-15.2
(x = 0 to 30%)
Pd—xTa	12-11.7
(x = 0 to 20%)
Pd—xAg	11.3-11.85
(x = 10 to 50%)
Pd—xPt	13-13.9
(x = 10 to 20%)
Pd—xAg—yCu	11.3-11.85
(x = 10 to 50%, y = 5 to 10%)
Pd—26% Ag—2% Ni	11.5
Pd—xRe—yW	12-16
(x = 0 to 20%, y = 0 to 30%)
Pd—9.5% Pt—9% Au—14% Cu—32.5% Ag	11.13

Of the alloys in Table 1, palladium alloys containing rhenium are preferred. Additionally, it has been found by the present inventors that a palladium alloy having, by weight, rhenium in the range of about 10 to 15 percent, preferably 10 to 15 percent, and more preferably in the range of about 11 to 14 percent, preferably 11 to 14 percent, produces an alloy with advantageous properties. Even more preferably, a palladium alloy having, by weight, rhenium at about 14 percent, or 14 percent, has been found to impart particularly advantageous properties over other alloys currently in use, as discussed above. Other preferred palladium alloys are those containing molybdenum. Other preferred palladium alloys are those containing silver, either alone or in combination with other elements. Of the palladium-molybdenum alloys, those containing over about 5 percent by weight molybdenum are preferred, preferably about 5 to 30 percent, preferably about 10 to 25 percent, preferably about 10 to 20 percent, preferably about 10 to 15 percent.
Table 1 also shows a preferred ternary palladium based alloy that includes silver in the range of about 10 to 50 percent and copper in the range of about 5 to 50 percent. It is believed that this alloy, as well as palladium alloys including ruthenium in the range of up to about 10 percent, can be strengthened using known precipitation hardening or age hardening methods. In addition, other suitable ternary or quaternary palladium based alloys are possible by alloying palladium with two or three different elements. For example, as shown in Table 1, palladium may be alloyed with about 26 percent silver and about 2 percent nickel, or with rhenium in the range of up to about 20 percent and tungsten in the range of up to about 30 percent, to form a suitable alloy. Furthermore, for example, palladium may be alloyed with about 9.5 percent platinum, about 9 percent gold, about 14 percent copper and about 32.5 percent silver to form a suitable alloy.
In the embodiment illustrated in FIG. 3 by a sectional view of the distal portion, one wire 20 or strand out of a group of three is of the palladium based alloys shown above in Table 1 and the remaining two 21 are of the high strength material. The wire 20 can have a relatively short length and be fixed in distal extension of a wire of the same type as wires 21. As an alternative, in the embodiment illustrated in FIG. 4, a wire guide distal portion 16 of the type shown in FIG. 2 can be provided with a coil 22 of wire made of the palladium based alloys shown above in Table 1. The coil 22 has a very small wire diameter, such as 0.05-0.35 mm. The coil has a pitch distance corresponding to the diameter of the wire, and consequently coil 22 is unable to transfer torque and is very flexible so that the desired properties of the distal wire guide portion are not impaired by adding coil 22 to the wire guide.
It will be understood by one of ordinary skill in the art that the wire guides described herein are intended as illustrative rather than limiting and that, according to the present invention, palladium based alloys are applicable to wire guides of different construction. For example, another embodiment according to the invention is outlined in FIG. 5 where distal end 2 is of the palladium based alloys shown above in Table 1 and includes a thread or a ribbon 23 of similar material that extends centrally into the hollow inner space in the wire guide to a free end. Alternatively, it is possible to position a distal end 2 designed as a very soft coil 24 of the palladium based alloys shown above in Table 1 in extension of wires 7, 8, 9 as outlined in FIG. 6. Such a coil can for example have a length 16 of about 35 mm. Apart from making the tip portion visible, coil 24 can also serve as a very soft and pliable tip member.
In another embodiment according to the invention, the use of palladium alloy material for the illustrative wire guide 1 can be extended by using a cored wire for the wire guide distal portion 16. In such a cored wire, the palladium alloy material could form a case on the outside of the wire while a secondary alloy, such as austenitic stainless steel, nickel titanium shape memory alloy(Nitinol) or a cobalt based superalloy such as L-605, MP35N or Elgiloy/Conichrome, could serve as the core on the inside. The palladium alloy material would provide for improved radiopacity and MRI compatibility while the secondary alloy would provide for high yield strength, high ultimate tensile strength and high stiffness for desired bending flexibility and pushability. Alternatively depending upon the desired bending flexibility and pushability, one of these secondary alloys could form the case on the outside of the wire while the palladium alloy material forms the core on the inside. Further, it should be recognized that secondary alloys such as martensitic stainless steel, precipitation hardening stainless steel, duplex stainless steel, maraging steel, music wire, Cr—V wire or rocket/missile wire could also be used to form the core.
The wire guide 1 may be used to introduce an embolization coil through a catheter in a blood vessel to limit or stop the free flow of blood at an occlusion site. FIG. 7 depicts an illustrative embolization coil 110 longitudinally positioned in a vessel 132 of a human or animal body. The embolization coil 110 has been formed into a conically helically shaped coil 115 having a longitudinal axis that is substantially aligned with the longitudinal axis of the vessel 132. The conically helically shaped coil 115 has a plurality of radially expanding turns 116 with thrombogenic fibers 126 spaced at predetermined intervals along the length of the coil. The conically helically shaped coil 115 extends over almost the entire cross-sectional area of the vessel lumen 135 to substantially impede blood flow and attract thrombus. The thrombogenic fibers of the embolization coil 110 more readily attract thrombus to further build up a mass that entirely occludes the vessel 132.
Due to the build up of plaque and other irregularities in the vessel wall, the vessel lumen 135 has a maximum diameter 133 and a minimum diameter 134 through any given length of the vessel 132. To ensure longitudinal alignment and fixed positioning of the embolization coil 110 in the vessel lumen 135, a distal turn 117 of the conically helically shaped coil 115 has a minor diameter 118 that is less than the minimum diameter 134 of the vessel 132, and a compressed proximal turn 119 of the conically helically shaped coil 115, when in an uncompressed condition, has a major diameter 120 that is greater than maximum diameter 133 of the vessel 132. This sizing of the conically helically shaped coil 115 ensures that the distal end 129 of the coil is introduced from a delivery catheter into the central region of the vessel 132. The successive turns of the conically helically shaped coil 115 radially increase in size as the embolization coil 110 is released from the delivery catheter to engage and expand against the interior surface or intimal layer of the vessel wall. As a result, the minor diameter distal turn 117 does not engage the vessel wall and longitudinally displace the delivery catheter positioned at the occlusion site. The proximal radially expanding turns of the conically helically shaped coil 115 centrally and longitudinally position the coil 115 in the vessel lumen 135. Furthermore, the most proximal turns of the conically helically shaped coil 115 readily expand against the interior surface of the vessel wall and fixedly position the coil 115 at the desired occlusion site. Precision positioning of the conically helically shaped coil 115 is thus readily achieved without concern for the embolization coil 110 emerging from the delivery catheter and tumbling or drifting to an undesired occlusion site in the vessel.
Further, the embolization coil 110 may be mounted on the wire guide 1 using known coupling means for achieving greater control over the positioning of the embolization coil in the catheter. For example, a threaded connection between the embolization coil 110 and the wire guide 1 may include a thread provided on distal end 2 of the wire guide 1 for screwing into a socket or connector attached to the proximal end of the embolization coil 110.
FIG. 8 depicts a partially sectioned view of the embolization coil 110 of FIG. 7 in an elongated condition prior to being wound into the conically helically shaped coil 115. The embolization coil 110 comprises a continuous wire strand 111 that has been wound in a well-known manner into a longitudinally extending coil 112 with a plurality of tightly spaced turns 113 and a hollow passage 114 extending longitudinally therein. For example, the continuous wire strand 111 is preferably wound into a longitudinally extending coil 112 approximately 6 cm long with a 0.014″ outside diameter and tightly spaced turns with minimal, if any, spacing 127 therebetween. Alternatively, the longitudinally extending coil 112 may be at least 6 cm long, perhaps about 6 to about 10 cm long, and the outside diameter can be at least 0.014″. Distal end 129 of the longitudinally extending coil is soldered or welded to present a rounded or smooth surface, which will not catch on the interior surface of the guiding catheter. The longitudinally extending coil 112 may be wound around a longitudinally tapered surface 138 of a mandril 123 to form the conically helically shaped coil 115 with minimally spaced turns 124, as shown in FIG. 9.
Continuous wire strand 111 comprises a metallic alloy material 122. In order to make the embolization coil 110 more visible on a screen it is desirable to use some kind of radiopaque material, such as a palladium based alloy which has equivalent or improved ultimate tensile strength and radiopacity compared to known platinum based alloys suitable for use in embolizations coils. For example, it is believed that a palladium alloy material 122 having, by weight, about 10 percent rhenium is preferable. This particular composition has a radiopacity approximately equivalent to a platinum alloy with 8 percent tungsten, an ultimate tensile strength of about 210 ksi, and a magnetic or bulk susceptibility of about 50×10⁻⁶SI when measured using a Guoy balance, as described above. The composition is also biocompatible and hemocompatible. It should be recognized that the high tensile strength properties of this composition may be improved by increasing the amount of rhenium in the composition or by modifying the drawing and annealing process for the wire.
It is also believed that a palladium alloy material 122 having, by weight, about 14 percent rhenium is preferable. This particular composition also has a radiopacity in the range of a platinum alloy with 8 percent tungsten, an ultimate tensile strength of about 270 ksi, and a magnetic or bulk susceptibility of about 25×10⁻⁶SI when measured using a Guoy balance, as described above. This composition is also biocompatible and hemocompatible. It has been found that such an alloy composition does not substantially magnetise, and thus use of this alloy in MR applications is of particular benefit. Specifically, when this composition is drawn into the wire strand 111, the drawn wire has an ultimate tensile strength of about 270 ksi and an elongation to fracture of about 3 to 4 percent. Such a high ultimate tensile strength has not before been achieved using these and similar alloys. It has been surprisingly found by the present inventors that the hardening experienced by the inventive alloys may result from work hardening (i.e. cold reductions in excess of about 90 to 95 percent), preferably without any interpass recrystallization anneals. This creates a very elongated grain structure with pancake-shaped grains that exhibit a high aspect ratio. Examination of these grains at very high magnification with a TEM (transmission electron microscope) reveals a well-defined subgrain structure with a high dislocation density. It is this high dislocation density that may give the alloy wire in the cold drawn condition its high yield and ultimate tensile strength. These properties are desirable because testing has shown that if the ultimate tensile strength of the drawn wire exceeds approximately 275 ksi, the drawn wire may fracture more easily when it is wound to form the embolization coil 110. Moreover, it is possible to subject the embolization coil 110 to a short term aging treatment to further improve its tensile strength properties after the drawn wire is wound and the shape of the embolization coil 110 is set. Such an aging process has been found to raise the ultimate tensile strength by about 5 to 30 ksi. For example, testing has shown that an aging treatment performed at a temperature of about 800 degrees Fahrenheit for a duration of about 20 minutes results in a wire having an ultimate tensile strength of about 300 ksi and an elongation to fracture of about a 2.5 to 3 percent.
Table 2 is a summary of the magnetic susceptibility and ultimate tensile strength of alloys of the present invention discussed above compared to presently used alloys:

TABLE 2

the additional rhenium in the Pd—14% Re composition allows
the alloy to be hardened.

	Magnetic
	susceptibility	Ultimate Tensile
Alloy composition	(SI units)	Strength (ksi)

304 V SS	3200 × 10⁻⁶	300
Inconel alloy 625	1200 × 10⁻⁶	300
Pt alloy (Pt—8% W)	250 × 10⁻⁶	200
Pd—10% Re	50 × 10⁻⁶	200-230
Pd—14% Re	25 × 10⁻⁶	270-300

It will be understood that it is possible to improve the tensile strength properties of the embolization coil 110 using other known methods, for example, precipitation hardening and solid solution strengthening. Further, it will be understood that it is possible to age the embolization coil 110 selectively, i.e., apply an aging treatment to portions of the embolization coil 110, in order to create a variable strength embolization coil. In this case, for example, the distal turn 117 of the embolization coil 110 would be softer and more pliable as compared to the proximal turn 119, or vice versa.
Alternatively, it is believed that a palladium alloy material having, by weight, about 22.5 percent silver and about 10 percent copper may be used. This particular composition has a radiopacity approximately equivalent to a platinum alloy with 8 percent tungsten and an ultimate tensile strength of about 190 ksi. This palladium based alloy is also substantially free of nickel, which is considered an undesired contaminant in the bloodstream of a patient.
In addition, as noted above, the palladium based alloys shown above in Table 1 are believed to exhibit at least equivalent or improved ultimate tensile strength and radiopacity compared to platinum alloys. Furthermore, these palladium based alloys have densities that are approximately 40% less than traditional platinum alloys. Accordingly, embolization coils made from one of these palladium based alloys could have a smaller diameter than prior embolization coils made from platinum based alloys.
It will be understood by one of ordinary skill in the art that the embolization coils described herein are intended as illustrative rather than limiting and that, according to the present invention, palladium based alloys are applicable to embolization coils of different construction. For example, in another embodiment according to the invention, the use of palladium alloy material 122 for the illustrative embolization coil 110 can be extended by using a cored wire for continuous wire strand 111. In such a cored wire, the palladium alloy material 122 could form a case on the outside of the wire while a secondary alloy, such as austenitic stainless steel, nickel titanium shape memory alloy(Nitinol) or a cobalt based superalloy such as L-605, MP35N or Elgiloy/Conichrome, could serve as the core on the inside. The palladium alloy material 122 would provide for improved radiopacity and MRI compatibility while the secondary alloy would provide for high yield strength, high ultimate tensile strength and high stiffness for recoil. Alternatively depending upon the desired spring properties, one of these secondary alloys could form the case on the outside of the wire strand 11 while the palladium alloy material 122 forms the core on the inside. Further, it should be recognized that secondary alloys such as martensitic stainless steel, precipitation hardening stainless steel, duplex stainless steel, maraging steel, music wire, Cr—V wire or rocket/missile wire could also be used to form the core.
Palladium alloys can advantageously be used in various applications of embolization coils to help treat e.g. aneurisms, or arteriovenous malformations in the brain. Since MRI is used routinely nowadays for scanning the brain, the present alloys present particular advantages over the alloys currently on the market (e.g. Pt—Ni or Pt—W alloys), since they have a smaller MRI ‘footprint’ and thus enable a clearer picture of the surrounding area to be obtained.
While the present invention has been described in terms of the above illustrative medical wire guides and embolization coils, it will be understood by one of ordinary skill in the art that, according to the present invention, palladium based alloys are applicable to other implantable medical devices, such as stents or filters, that are introduced temporarily or permanently in a body passage or lumen to treat a variety of medical conditions.
For example, in another embodiment according to the present invention, radiopaque marker bands for catheters are made from palladium based alloys as described herein. A marker band typically comprises a tubular body that is disposed at predetermined position on the exterior surface of a catheter. Such marker bands can be manufactured from seamless or welded and drawn tubing, which is made from one of the palladium based alloys listed in Table 1. Alternatively, radiopaque marker bands having a porous surface can be made from one of the palladium based alloys listed in Table 1 using a known metal foam manufacturing process, such as that used to manufacture trabecular metal by depositing chemical vapors onto a foam substrate. A porous maker band constructed using a metal foam manufacturing process would use less palladium by volume than marker bands made using seamless or welded and drawn tubing. Radiopaque marker bands also can be constructed from clad tubing that, according to the present invention, has a clad layer that is made from one of the palladium based alloys listed in Table 1. For example, powder particles of one of the palladium based alloys listed in Table 1 are deposited on the outer surface of a tubing of austenitic stainless steel, nickel titanium shape memory alloy (Nitinol) or a cobalt based superalloy such as L-605, MP35N or Elgiloy/Conichrome, using known methods such that the palladium based alloy particles are bonded to the surface of the tubing. Radiopaque marker bands also can be constructed from one of the palladium based alloys listed in Table 1 using known ceramic or metal injection molding processes in which a powder of one of the palladium based alloys is mixed with a “binder” material such as plastic and then injected into a mold of the desired shape, for example a tubular body, which is then sintered at a higher temperature to consolidate the alloy powder. The “binder” material is then be removed from the molded part, for example, using standard solvent extraction techniques.
According to another embodiment, radiopaque RF ablation coils and radiopaque electrodes are made from palladium based alloys as described herein. RF ablation coils and electrodes used for treatment of atrial fibulation and atrial flutter and to map electrograms typically are made from a radiopaque and conductive material. The use of a radiopaque material allows a physician to guide the coils and electrodes to a target site. The use of a conductive material creates a conduction path for ablation of surrounding tissue.
For example, conventional radiofrequency catheter ablation techniques for treating a variety of cardiac arrhythmias typically use RF ablation coils made from platinum wire disposed about the tip of a catheter. The RF ablation coils are introduced within the body and are positioned at a desired site using the catheter. A physician can monitor the progress of the RF ablation coils in the body since the platinum renders them radiopaque. The ablation catheter can be maneuvered to various locations around the heart in a magnetic resonance imaging (MRI) system to acquire data for mapping electrograms. The ablation catheter is also used to position the RF ablation coil at the target site for treating the arrhythmia. Since the coil is conductive, a radiofrequency energy applied to the coil causes an electrical current to flow in the tissue surrounding the coil for ablating the target tissue.
As noted above, the palladium based alloys shown above in Table 1 are believed to offer equivalent or better material properties, including tensile strength, radiopacity and MR compatibility, compared to known platinum based alloys and austenitic stainless steel alloys. In addition, it is believed that these palladium based alloys exhibit similar heat transfer properties compared to known platinum alloys. For example, the thermal conductivity of palladium is approximately 0.168 cal/sq cm/cm/s degree C. and the thermal conductivity of platinum is about 0.165 cal/sq cm/cm/s degree C. Furthermore, these palladium based alloys have densities that are approximately 40% less than traditional platinum alloys. Accordingly, RF ablation coils and electrodes made from one of these palladium based alloys could have a smaller diameter than prior RF ablation coils and electrodes made from platinum based alloys.
It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intended to define the spirit and scope of this invention.

Claims

1. A magnetic resonance imaging method comprising:

placing a subject in a magnetic field, the subject having an implantable device at least partially implanted therein, wherein the implantable device comprises at least one portion made of a palladium alloy having, by weight, rhenium in the range of about 5 to 15 percent; and

visualizing the at least one portion of the implantable device or a surrounding region within the subject using magnetic resonance imaging.

2. The method of claim 1, wherein the implantable medical device is a wire guide.

3. The method claim 2, wherein the wire guide includes a coiled distal portion made of the palladium alloy.

4. The method claim 2, wherein the wire guide includes a coil made of the palladium alloy disposed about a distal portion.

5. The method claim 2, wherein the wire guide includes a distal end made of the palladium alloy, the distal end having a thread that extends centrally into the wire guide.

6. The method claim 2, wherein the wire guide includes a cored wire having at least one section made of the palladium alloy.

7. The method claim 1, wherein the implantable medical device is an embolization coil.

8. The method claim 7, wherein the embolization coil includes a coiled wire made at least in part of the palladium alloy.

9. The method claim 8, wherein the coiled wire comprises a conically helically shaped coil made of the palladium alloy, the coil having a plurality of radially expanding turns.

10. The method claim 8, wherein the coiled wire comprises a cored wire having at least one section made of the palladium alloy.

11. The method claim 1, wherein the implantable medical device is a marker band.

12. The method claim 1, wherein the implantable medical device is a stent.

13. The method claim 1, wherein the implantable medical device is a filter.

14. The method claim 1, wherein the implantable medical device is a RF ablation coil.

15. The method claim 1, wherein the implantable medical device is an electrode.

16. The method claim 1, wherein the palladium alloy has, by weight, about 10 percent rhenium.

17. The method claim 1, wherein the palladium alloy has, by weight, about 14 percent rhenium.

18. A magnetic resonance imaging method comprising:

placing a subject in a magnetic field, the subject having an implantable device at least partially implanted therein, wherein the implantable device comprises at least one portion made of a palladium alloy having a magnetic susceptibility of about 50×10⁻⁶SI when measured using a Guoy balance; and

19. The method claim 18, wherein the implantable medical device is selected from the group consisting of a wire guide, an embolization coil, a marker band, a stent, a filter, a RF ablation coil, and an electrode.

20. The method claim 18, wherein the palladium alloy is an alloy of palladium and rhenium.